Apparatus and method for transmitting/receiving pilot signal in communication system using OFDM scheme
Abstract
Disclosed is a method for transmitting a reference signal for identification of each cell in a communication system including a plurality of cells each of which is identified by a cell identifier. The method includes receiving a cell identifier, and generating a block code corresponding to the cell identifier using a predetermined block code generator matrix, and generating a first part sequence using the block code; selecting a second part sequence in accordance with the cell identifier; generating a reference signal of a frequency domain using the first part sequence and the second part sequence; converting the reference signal of the frequency domain to a reference signal of a time domain through an Inverse Fast Fourier Transform operation and transmitting the reference signal of the time domain in a predetermined reference signal transmission interval.
Claims
exact text as granted — not AI-modified1. A method for transmitting a reference signal for identification of each cell in a communication system including a plurality of cells each of which is identified by a cell identifier, the method comprising the steps of:
in response to input of the cell identifier, generating, by a block code encoder, a block code corresponding to the cell identifier using a predetermined block code generator matrix;
generating a first part sequence by interleaving, by an interleaver, the block code according to at least one interleaving scheme and performing, by an adder, an exclusive OR operation on the interleaved block code;
selecting a second part sequence corresponding to the cell identifier and from among predetermined sequences considering Peak-to-Average Power Ratio (PAPR) reduction;
generating, by a combiner, a reference signal of a frequency domain by using the first part sequence and the second part sequence;
converting, by a transmitter, the reference signal of the frequency domain to a reference signal of a time domain through an Inverse Fast Fourier Transform (IFFT) operation; and
transmitting, by the transmitter, the reference signal of the time domain in a over a reference signal transmission interval,
wherein the reference signal of the frequency domain is defined by:
P
ID
cell
,
S
[
k
]
=
{
2
(
1
-
2
q
ID
cell
,
S
[
m
]
)
,
k
=
2
m
-
N
used
2
,
m
=
0
,
1
,
…
,
N
used
4
-
1
2
(
1
-
2
q
ID
cell
,
S
[
m
-
1
]
)
,
k
=
2
m
-
N
used
2
,
m
=
N
used
4
+
1
,
N
used
4
+
2
,
…
,
N
used
2
0
,
otherwise
ID
cell
∈
{
0
,
1
,
…
,
126
}
,
s
∈
{
0
,
1
,
…
,
7
}
,
k
∈
{
-
N
FFT
/
2
,
-
N
FFT
/
2
+
1
,
…
,
N
FFT
2
-
1
}
,
where P ID cell,S [k] denotes the reference signal, ID cell denotes the cell identifier, s denotes a sector identifier, k denotes a sub-carrier index, N used denotes a number of used subcarriers, N FFT denotes a number of points of the IFFT operation, and q IDcell,S [m] denotes a setup sequence.
2. The method as claimed in claim 1 , wherein the step of converting the reference signal comprises the steps of:
inserting null data into sub-carriers corresponding to DC components and intersubcarrier interference eliminating components from among N sub-carriers;
inserting elements of the reference signal into M sub-carriers other than the sub-carriers into which the null data is inserted from among the N sub-carriers; and
performing an IFFI operation on a signal including the reference signal elements and the M sub-carriers and then transmitting the signal.
3. The method as claimed in claim 2 , wherein inserting elements of the reference signal is performed in consideration of a predetermined offset that is set to have a specific value for each of the cells and sectors.
4. The method as claimed in claim 1 , wherein the setup sequence is defined by:
q
ID
cell
,
S
[
m
]
=
{
R
(
8
*
⌊
m
9
⌋
+
m
mod
9
)
,
where
m
mod
9
=
0
,
1
,
…
,
7
m
=
0
,
1
,
…
,
53
T
(
⌊
m
9
⌋
)
,
where
m
mod
9
=
8
,
wherein └m/9┘ represents a maximum integer not greater than m/9, and R(r) is defined by:
R
(
r
)
=
w
r
mod
8
s
⊕
b
IDcell
+
1
g
∏
(
r
)
,
r
=
8
*
⌊
m
9
⌋
+
m
mod
9
=
0
,
1
,
…
,
47
,
wherein w s r mod8 represents repetition of Walsh codes having a length of 8, b k (1≦k≦47) represents a k-th row vector of the block code generator matrix, k represents a value calculated by adding a cell identifier IDcell and 1, g u (0≦u ≦47) represents a u-th column vector of the block code generator matrix, u represents indicating an r-th element of an interleaving pattern according to an interleaving scheme Π(r), R(r) denotes a first sequence, and T(−) denotes a second sequence.
5. The method as claimed in claim 4 , wherein the block code generator matrix is defined as
6. The method as claimed in claim 5 , wherein the interleaving scheme is defined by Π(r) as shown:
Π(r)
9, 7, 14, 15, 10, 1, 2, 5, 3, 8, 0, 4, 13, 11, 6, 12, 27, 29, 21, 18,
16, 25, 23, 17, 24, 19, 28, 31, 26, 20, 30, 22, 38, 47, 41, 42, 37,
46, 39, 45, 32, 34, 40, 33, 35, 43, 36, 44,
wherein each number in the table indicates an index of a sub-carrier to which an element of the block code is one-to-one mapped.
7. An apparatus for transmitting a reference signal for identification of each cell in a communication system including a plurality of cells each of which is identified by a cell identifier, the apparatus comprising:
a block code encoder which, in response to input of the cell identifier, generates a block code corresponding to the cell identifier by using a predetermined block code generator matrix;
an interleaver for interleaving the block code according to at least one interleaving scheme;
an adder for performing an exclusive OR operation on the interleaved block code, thereby generating a first part sequence;
a combiner for generating a reference signal of a frequency domain by using the first part sequence and a second part sequence which is selected corresponding to the cell identifier and from among predetermined sequences; and
a transmitter for converting the reference signal of the frequency domain to a reference signal of a time domain through an Inverse Fast Fourier Transform (IFFT) and, operation and then transmitting the reference signal of the time domain over a reference signal transmission interval,
where the reference signal of the frequency domain is defined by:
P
ID
cell
,
S
[
k
]
=
{
2
(
1
-
2
q
ID
cell
,
S
[
m
]
)
,
k
=
2
m
-
N
used
2
,
m
=
0
,
1
,
…
,
N
used
4
-
1
2
(
1
-
2
q
ID
cell
,
S
[
m
-
1
]
)
,
k
=
2
m
-
N
used
2
,
m
=
N
used
4
+
1
,
N
used
4
+
2
,
…
,
N
used
2
0
,
otherwise
ID
cell
∈
{
0
,
1
,
…
,
126
}
,
s
∈
{
0
,
1
,
…
,
7
}
,
k
∈
{
-
N
FFT
/
2
,
-
N
FFT
/
2
+
1
,
…
,
N
FFT
2
-
1
}
,
wherein P ID cell,S [k] denotes the reference signal, ID cell denotes the cell identifier, s denotes the sector identifier, k denotes a sub-carrier index, N used denotes a number of used subcarriers, N FFT denotes a number of points of the IFFT operation, and q IDcell,S [m] denotes a setup sequence.
8. The apparatus as claimed in claim 7 , wherein the block code generator matrix includes b number of sub-blocks, each of which includes c number of Walsh bases and d number of mask sequences, and the b sub-blocks including a first sub-block to a b-th sub-block have a relation of cyclic shift between each other, so as to maximize a minimum distance of the block code generated by using the block code generator matrix.
9. The apparatus as claimed in claim 8 , wherein the interleaver divides the block code into the b sub-blocks and interleaves the b sub-blocks according to b number of interleaving schemes differently set for the b sub-blocks.
10. The apparatus as claimed in claim 7 , wherein the transmitter comprises:
an Inverse Fast Fourier Transform (IFFT) unit for inserting null data into sub-carriers corresponding to DC components and intersubcarrier interference eliminating components from among N sub-carriers, inserting elements of the reference signal into M sub-carriers other than the sub-carriers into which the null data is inserted from among the N sub-carriers, and then performing an IFFT operation on a signal including the reference signal of the frequency domain elements and the M sub-carriers; and
a Radio Frequency (RF) processor for processing and transmitting the IFFT-processed signal.
11. The apparatus as claimed in claim 7 , wherein the transmitter comprises:
an IFFT unit for inserting null data into sub-carriers corresponding to DC components and intersubcarrier interference eliminating components from among N sub-carriers, inserting elements of the reference signal into M sub-carriers other than the sub-carriers into which the null data is inserted from among the N sub-carriers, in consideration of a predetermined offset, and then performing an IFFT operation on a signal including the reference signal of the frequency domain elements and the M sub-carriers and then transmitting the signal; and
a Radio Frequency (RF) processor for processing and transmitting the IFFT-processed signal.
12. The apparatus as claimed in claim 11 , wherein the offset is set to have a specific value for each of the cells and sectors.
13. The apparatus as claimed in claim 7 , wherein the setup sequence is defined by:
q
ID
cell
,
S
[
m
]
=
{
R
(
8
*
⌊
m
9
⌋
+
m
mod
9
)
,
where
m
mod
9
=
0
,
1
,
…
,
7
m
=
0
,
1
,
…
,
53
T
(
⌊
m
9
⌋
)
,
where
m
mod
9
=
8
,
wherein
⌊
m
9
⌋
represents a maximum integer not greater than
m
9
,
and R(r) is defined by:
R
(
r
)
=
w
r
mod
8
s
⊕
b
IDcell
+
1
g
∏
(
r
)
,
r
=
8
*
⌊
m
9
⌋
+
m
mod
9
=
0
,
1
,
…
,
47
,
wherein w s r mod8 represents repetition of Walsh codes having a length of 8, b k (1≦k≦47) represents a k-th row vector of the block code generator matrix, k represents a value calculated by adding a cell identifier IDcell and 1, g u (0≦u≦47) represents a u-th column vector of the block code generator matrix, u represents indicating an r-th element of an interleaving pattern according to an interleaving scheme Π(r), R(r) denotes a first sequence, and T(−) denotes a second sequence.
14. The apparatus as claimed in claim 13 , wherein the block code generator matrix is expressed as
15. The apparatus as claimed in claim 14 , wherein the interleaving scheme is defined as Π(r) as shown:
Π(r)
9, 7, 14, 15, 10, 1, 2, 5, 3, 8, 0, 4, 13, 11, 6, 12, 27, 29, 21, 18,
16, 25, 23, 17, 24, 19, 28, 31, 26, 20, 30, 22, 38, 47, 41, 42, 37,
46, 39, 45, 32, 34, 40, 33, 35, 43, 36, 44,
wherein each number in the table indicates an index of a sub-carrier to which an element of the block code is one-to-one mapped.
16. A method for receiving a reference signal for identification of each cell in a communication system including a plurality of cells each of which is identified by a cell identifier, the method comprising:
extracting, by a reference signal extractor, the reference signal from a received signal which has been converted through a Fast Fourier Transform (FFT) operation;
dividing, by an adder, the reference signal into a predetermined number of intervals and performing an exclusive OR (XOR) operation on the divided intervals;
deinterleaving, by a deinterleaver, the XOR-processed signal according to at least one deinterleaving scheme;
dividing, by a sub-block divider, the deinterleaved signal into sub-block signals in accordance with a predetermined block code generator matrix;
performing, by a block code decoder, an Inverse Fast Hadamard Transform (IFHT) using mask sequences generated according to control of each of the sub-block signals;
generating, by a combiner, a combined signal by combining the IFHT-processed signals for each of the sub-block signals; and
determining, by a comparison selector, a cell identifier corresponding to a block code having a maximum correlation value from among the combined signals as a final cell identifier,
wherein the reference signal of the frequency domain is defined by:
P
ID
cell
,
S
[
k
]
=
{
2
(
1
-
2
q
ID
cell
,
S
[
m
]
)
,
k
=
2
m
-
N
used
2
,
m
=
0
,
1
,
…
,
N
used
4
-
1
2
(
1
-
2
q
ID
cell
,
S
[
m
-
1
]
)
,
k
=
2
m
-
N
used
2
,
m
=
N
used
4
+
1
,
N
used
4
+
2
,
…
,
N
used
2
0
,
otherwise
ID
cell
∈
{
0
,
1
,
…
,
126
}
,
s
∈
{
0
,
1
,
…
,
7
}
,
k
∈
{
-
N
FFT
/
2
,
-
N
FFT
/
2
+
1
,
…
,
N
FFT
2
-
1
}
,
wherein P ID cell,S [k] denotes the reference signal, ID cell denotes the cell identifier, s denotes the sector identifier, k denotes a sub-carrier index, N used denotes a number of subcarriers used, N FFT denotes a number of points of the IFFT operation, and q IDcell,S [m] denotes a setup sequence.
17. The method as claimed in claim 16 , wherein, in the step of extracting, the reference signal is extracted by eliminating a predetermined sequence from a signal received through M sub-carriers other than sub-carriers corresponding to DC components and intersubcarrier interference eliminating components from among N sub-carriers.
18. The method as claimed in claim 17 , wherein the eliminating is performed in consideration of a predetermined offset that is set to have a specific value for each of the cells and sectors.
19. The method as claimed in claim 16 , wherein the setup sequence is defined by:
q
ID
cell
,
S
[
m
]
=
{
R
(
8
*
⌊
m
9
⌋
+
m
mod
9
)
,
where
m
mod
9
=
0
,
1
,
…
,
7
m
=
0
,
1
,
…
,
53
T
(
⌊
m
9
⌋
)
,
where
m
mod
9
=
8
,
wherein
⌊
m
9
⌋
represents a maximum integer not greater than
m
9
,
and R(r) is defined by:
R
(
r
)
=
w
r
mod
8
s
⊕
b
IDcell
+
1
g
∏
(
r
)
,
r
=
8
*
⌊
m
9
⌋
+
m
mod
9
=
0
,
1
,
⋯
,
47
,
wherein w s r mod8 represents repetition of Walsh codes having a length of 8, b k (1≦k≦47) represents a k-th row vector of the block code generator matrix, k represents a value calculated by adding a cell identifier IDcell and ‘1’, g u (0≦u≦47) represents a u-th column vector of the block code generator matrix, u represents indicating an r-th element of an interleaving pattern according to a deinterleaving scheme Π(r), R(r) denotes a first sequence, and T(−) denotes a second sequence.
20. The method as claimed in claim 19 , wherein the block code generator matrix is defined as:
21. The method as claimed in claim 20 , wherein the deinterleaving scheme is defined to correspond to an interleaving scheme Π(r) as shown in:
Π(r)
9, 7, 14, 15, 10, 1, 2, 5, 3, 8, 0, 4, 13, 11, 6, 12, 27, 29, 21, 18,
16, 25, 23, 17, 24, 19, 28, 31, 26, 20, 30, 22, 38, 47, 41, 42, 37,
46, 39, 45, 32, 34, 40, 33, 35, 43, 36, 44,
wherein each number in the table indicates an index of a sub-carrier to which an element of the block code is one-to-one mapped.
22. The method as claimed in claim 21 , wherein the setup sequence is set to have a minimum Peak to Average Power Ratio (PAPR) for the reference signal.
23. An apparatus for receiving a reference signal for identification of each cell in a communication system including a plurality of cells each of which is identified by a cell identifier, the apparatus comprising:
a Fast Fourier Transform (FFT) unit for performing an FFT operation on a received signal;
a reference signal extractor for extracting the reference signal from the FFT-processed signal;
an adder for dividing the reference signal into a predetermined number of intervals and performing an exclusive OR (XOR) operation on the divided intervals;
a deinterleaver for deinterleaving the XOR-processed signal according to at least one deinterleaving scheme;
a sub-block divider for dividing the deinterleaved signal into sub-block signals in accordance with a predetermined block code generator matrix;
a block code decoder for performing an Inverse Fast Hadamard Transform (IFHT) using mask sequences generated according to control of each of the sub-block signals;
a combiner for generating a combined signal by combining the IFHT-processed signals for each of the sub-block signals; and
a comparison selector for determining a cell identifier corresponding to a block code having a maximum correlation value from among the combined signals as a final cell identifier,
wherein the reference signal of the frequency domain is defined by:
P
ID
cell
,
S
[
k
]
=
{
2
(
1
-
2
q
ID
cell
,
S
[
m
]
)
,
k
=
2
m
-
N
used
2
,
m
=
0
,
1
,
…
,
N
used
4
-
1
2
(
1
-
2
q
ID
cell
,
S
[
m
-
1
]
)
,
k
=
2
m
-
N
used
2
,
m
=
N
used
4
+
1
,
N
used
4
+
2
,
…
,
N
used
2
0
,
otherwise
ID
cell
∈
{
0
,
1
,
…
,
126
}
,
s
∈
{
0
,
1
,
…
,
7
}
,
k
∈
{
-
N
FFT
/
2
,
-
N
FFT
/
2
+
1
,
…
,
N
FFT
2
-
1
}
,
where P ID cell,S [k] denotes the reference signal of the frequency domain, ID cell denotes the cell identifier, s denotes the sector identifier, k denotes a sub-carrier index, N used denotes a number of used subcarriers, N FFT denotes a number of points of the FFT operation, and q IDcell,S [m] denotes a setup sequence.
24. The apparatus as claimed in claim 23 , wherein the reference signal extractor extracts the reference signal by eliminating a predetermined sequence from a signal received through M sub-carriers other than sub-carriers corresponding to DC components and intersubcarrier interference eliminating components from among N sub-carriers.
25. The apparatus as claimed in claim 24 , wherein the eliminating is performed in consideration of a predetermined offset that is set to have a specific value for each of the cells and sectors.
26. The apparatus as claimed in claim 23 , wherein the setup sequence is defined by:
q
ID
cell
,
S
[
m
]
=
{
R
(
8
*
⌊
m
9
⌋
+
m
mod
9
)
,
where
m
mod
9
=
0
,
1
,
…
,
7
m
=
0
,
1
,
…
,
53
T
(
⌊
m
9
⌋
)
,
where
m
mod
9
=
8
,
wherein
⌊
m
9
⌋
represents a maximum integer not greater than
m
9
.
and R(r) is defined by:
R
(
r
)
=
w
r
mod
8
s
⊕
b
IDcell
+
1
g
∏
(
r
)
,
r
=
8
*
⌊
m
9
⌋
+
m
mod
9
=
0
,
1
,
…
,
47
,
wherein w s r mod8 represents repetition of Walsh codes having a length of 8, b k (1≦k≦47) represents a k-th row vector of the block code generator matrix, k represents a value calculated by adding a cell identifier IDcell and ‘1’, g u (0≦u ≦47) represents a u-th column vector of the block code generator matrix, u represents indicating an r-th element of an interleaving pattern according to a deinterleaving scheme Π(r), R(r) denotes a first sequence, and T(−) denotes a second sequence.
27. The apparatus as claimed in claim 23 , wherein the block code generator matrix is defined as:
28. The apparatus as claimed in claim 27 , wherein the deinterleaving scheme corresponds to an interleaving scheme Π(r) as shown in:
Π(r)
9, 7, 14, 15, 10, 1, 2, 5, 3, 8, 0, 4, 13, 11, 6, 12, 27, 29, 21, 18,
16, 25, 23, 17, 24, 19, 28, 31, 26, 20, 30, 22, 38, 47, 41, 42, 37,
46, 39, 45, 32, 34, 40, 33, 35, 43, 36, 44,
wherein each number in the table indicates an index of a sub-carrier to which an element of the block code is one-to-one mapped.
29. The apparatus as claimed in claim 28 , wherein the setup sequence is set to have a minimum Peak to Average Power Ratio (PAPR) for the reference signal.
30. A method for transmitting a reference signal for identification of each cell through at least one transmit antenna in a communication system including a plurality of cells each of which is identified by a cell identifier, the method comprising:
receiving a cell identifier;
generating, by a block code encoder, a block code corresponding to the cell identifier by using a predetermined block code generator matrix;
selecting a Walsh code corresponding to the cell identifier from among predetermined Walsh codes, and repeating the selected Walsh code a predetermined number of times;
interleaving, by an interleaver, the block code according to at least one interleaving scheme and performing, by an adder, an exclusive OR operation on the interleaved block code and the repeated Walsh code, thereby generating a first part sequence;
selecting a second part sequence corresponding to the cell identifier from among predetermined sequences;
generating, by a combiner, a reference signal of a frequency domain by using the first part sequence and the second part sequence; and
converting, by a transmitter, the reference signal of the frequency domain to a reference signal of a time domain through an Inverse Fast Fourier Transform (IFFT) operation and then transmitting the reference signal of the time domain in a predetermined reference signal transmission interval,
wherein the reference signal of the frequency domain is defined by:
P
ID
cell
,
n
[
k
]
=
{
1
-
2
q
ID
cell
[
m
]
,
k
=
N
t
m
-
N
used
2
+
n
,
m
=
0
,
1
,
…
,
N
used
N
t
-
1
0
,
otherwise
ID
cell
∈
{
0
,
1
,
…
,
126
}
,
n
=
0
,
1
,
…
N
t
-
1
,
k
∈
{
-
N
FFT
2
,
-
N
FFT
2
+
1
,
…
,
N
FFT
2
-
1
}
,
where P ID cell,S [k] denotes the reference signal, ID cell denotes the cell identifier, n denotes an index of one of the transmit antennas, k denotes a sub-carrier index, N FFT denotes a number of points of the IFFT operation, N used denotes a number of used subcarriers, N t indicates a number of the transmit antennas, and q IDcell,S [m] denotes a setup sequence.
31. The method as claimed in claim 30 , wherein the block code generator matrix includes b number of sub-blocks, each of which includes c number of Walsh bases and d number of mask sequences.
32. The method as claimed in claim 31 , wherein the b sub-blocks including a first sub-block to a b-th sub-block have a relation of cyclic shift between each other, so as to maximize the minimum distance of the block code generated by using the block code generator matrix.
33. The method as claimed in claim 31 , wherein the step of interleaving comprises the steps of:
dividing the block code into the b sub-blocks; and
interleaving the b sub-blocks according to b number of interleaving schemes differently set for the b sub-blocks.
34. The method as claimed in claim 33 , wherein the step of converting comprises the steps of:
inserting null data into sub-carriers corresponding to DC components and intersubcarrier interference eliminating components from among N sub-carriers;
inserting elements of the reference signal into M sub-carriers other than the sub-carriers into which the null data is inserted from among the N sub-carriers; and
performing an Inverse Fast Fourier Transform (IFFT) operation on a signal including the reference signal elements and the M sub-carriers.
35. The method as claimed in claim 33 , wherein the step of converting comprises the steps of:
inserting null data into sub-carriers corresponding to DC components and intersubcarrier interference eliminating components from among N sub-carriers;
inserting elements of the reference signal into M sub-carriers other than the sub-carriers into which the null data is inserted from among the N sub-carriers, in consideration of a predetermined offset; and
performing an IFFT operation on a signal including the reference signal elements and the M sub-carriers and then transmitting the signal.
36. The method as claimed in claim 35 , wherein the offset is set to have a specific value for each of the cells and sectors.
37. The method as claimed in claim 30 , wherein the setup sequence is defined by:
q
ID
cell
[
m
]
=
{
R
(
8
*
⌊
m
9
⌋
+
m
mod
9
)
,
where
m
mod
9
=
0
,
1
,
…
,
7
m
=
0
,
1
,
…
,
N
used
N
t
-
1
T
(
⌊
m
9
⌋
)
,
where
m
mod
9
=
8
,
wherein
⌊
m
9
⌋
represents a maximum integer not greater than
m
9
,
R(r) denotes a first sequence, and T(−) denotes a second sequence.
38. The method as claimed in claim 37 , wherein R(r) is defined by an equation,
R
(
r
)
=
B
IDcell
+
1
g
∏
(
r
)
,
r
=
8
*
⌊
m
9
⌋
+
m
mod
9
=
0
,
1
,
…
,
47
,
wherein the number of the transmit antennas is two, the number of operation points of the FFT operation is 128, b k represents a k-th row vector of the block code generator matrix, k represents a value calculated by adding a cell identifier IDcell and 1, g u (0≦u≦47) represents a u-th column vector of the block code generator matrix, and u represents indicating an r-th element of a interleaving pattern according to an interleaving scheme Π(r).
39. The method as claimed in claim 38 , wherein the block code generator matrix is defined as:
40. The method as claimed in claim 38 , wherein the interleaving scheme is defined by Π(r) as shown in:
Π(l)
5, 6, 4, 10, 7, 2, 14, 0, 8, 11, 13, 12, 3, 15, 1, 9, 26, 29, 19, 27,
31, 17, 20, 16, 23, 28, 24, 21, 18, 30, 25, 22, 43, 46, 34, 47, 44,
41, 37, 36, 39, 38, 35, 33, 32, 45, 40, 42,
wherein each number in the table indicates an index of a sub-carrier to which an element of the block code is one-to-one mapped.
41. The method as claimed in claim 38 , wherein T(k) has one of values as expressed in:
ID cell
sequence
papr
0
1 1 1 0 1 1
6.67057
1
0 0 1 1 0 0
5.883
2
1 1 1 1 1 1
4.95588
3
0 1 1 0 0 1
4.92942
4
1 0 0 1 0 0
4.84232
5
0 1 0 1 0 0
5.97707
6
0 0 0 0 1 1
5.2818
7
0 1 1 1 0 1
4.62935
8
1 1 1 1 0 1
4.80191
9
0 1 1 1 1 0
4.62839
10
1 0 0 0 0 0
4.93818
11
0 0 0 0 1 0
4.62239
12
1 1 0 0 1 1
5.23206
13
0 0 0 0 0 1
4.76556
14
1 1 0 1 1 1
5.21957
15
0 1 1 0 0 0
6.73261
16
0 0 1 1 1 0
4.9981
17
0 1 1 0 0 0
5.23977
18
1 1 1 1 1 0
5.59862
19
0 1 1 1 0 1
6.75846
20
0 0 1 1 1 1
4.86729
21
1 1 0 0 0 0
5.57405
22
1 0 1 0 0 1
4.82309
23
0 1 0 1 0 1
4.54948
24
0 1 1 1 0 1
5.45765
25
1 1 0 0 0 1
4.91648
26
1 0 0 1 0 1
3.95813
27
1 0 0 0 0 1
6.03433
28
1 1 0 0 0 1
4.50629
29
0 1 0 0 0 1
4.80454
30
1 0 1 1 1 1
4.94614
31
1 0 1 1 0 0
4.54236
32
0 1 1 0 0 0
5.66311
33
0 1 1 0 0 0
5.18297
34
1 1 0 1 0 1
5.59197
35
1 0 0 1 0 0
5.51692
36
1 1 0 0 1 0
4.64969
37
1 1 1 0 0 0
5.59862
38
0 0 0 0 1 1
5.56593
39
1 0 1 0 0 0
6.65257
40
0 0 1 0 1 1
6.30837
41
0 0 0 1 0 1
5.76988
42
0 0 0 1 1 1
5.17799
43
1 0 0 1 1 0
5.50595
44
0 0 0 0 0 1
5.58222
45
1 1 1 0 1 1
5.19814
46
1 0 0 1 1 0
5.50865
47
1 0 0 0 0 0
5.40509
48
1 0 0 1 0 0
4.48416
49
0 1 0 0 1 1
5.59862
50
0 1 0 1 0 0
4.76609
51
0 1 1 1 0 1
4.87035
52
1 1 1 0 0 1
5.60052
53
1 0 1 0 0 1
4.18939
54
1 1 1 1 0 1
5.00411
55
1 1 1 1 0 0
4.91284
56
0 0 0 0 1 0
6.92296
57
0 0 0 0 1 0
5.39012
58
0 1 1 0 0 1
6.0232
59
1 1 0 1 0 0
5.27241
60
0 0 1 0 1 0
5.26582
61
1 0 0 0 0 1
5.47146
62
0 0 0 0 1 0
6.43249
63
1 0 0 1 1 1
4.69906
64
1 1 1 0 0 0
5.28969
65
1 0 1 0 1 1
6.66965
66
1 0 1 0 1 1
5.90593
67
0 1 1 1 0 0
6.13642
68
0 0 1 0 0 0
4.9337
69
0 1 1 0 1 0
5.19715
70
1 1 1 1 0 0
5.05877
71
1 0 0 1 0 0
5.42538
72
1 1 1 0 1 0
5.21428
73
1 0 1 1 0 1
4.27288
74
0 1 0 0 0 1
4.63478
75
1 0 1 0 0 1
5.47216
76
1 0 1 0 0 0
6.48514
77
1 1 0 0 0 0
5.95897
78
0 0 0 0 0 1
5.59862
79
0 1 0 0 0 0
5.36634
80
0 0 0 0 1 0
4.79522
81
0 0 1 1 1 0
5.03585
82
1 1 0 0 1 1
6.41538
83
0 1 1 0 0 1
5.92329
84
1 0 1 1 1 0
5.24541
85
0 0 0 0 0 1
6.41868
86
1 0 1 0 1 1
5.47231
87
0 1 0 1 1 1
4.27052
88
0 0 0 1 0 1
4.98455
89
0 0 0 1 0 1
4.85573
90
1 0 1 1 0 0
4.66224
91
0 1 1 0 0 1
5.59862
92
0 1 0 1 0 1
5.13782
93
1 1 0 9 0 0
5.73599
94
0 1 1 1 1 1
6.91115
95
0 1 1 1 0 1
4.76096
96
0 1 0 1 1 1
4.43229
97
1 0 0 1 1 1
4.52951
98
1 0 0 1 0 0
4.16266
99
1 1 1 0 1 0
5.72573
100
0 1 0 1 0 0
4.34746
101
1 0 0 1 0 0
6.81937
102
0 1 0 1 1 1
5.86829
103
0 1 0 1 1 0
5.22098
104
1 0 0 0 0 0
4.8724
105
0 1 1 0 1 1
6.7658
106
1 0 0 0 1 0
5.75267
107
1 1 0 0 1 1
5.1796
108
1 1 1 0 0 0
6.00083
109
1 0 1 0 0 1
4.6724
110
1 0 0 1 0 0
4.8945
111
0 0 1 1 1 0
4.05646
112
0 0 1 1 1 1
5.6271
113
0 1 1 1 1 1
5.59862
114
1 1 0 0 1 0
4.80494
115
0 0 1 1 0 0
5.95286
116
0 1 1 0 0 1
5.99303
117
0 1 0 0 1 1
3.97648
118
0 1 0 1 0 0
5.71222
119
0 0 0 0 1 1
4.61998
120
1 1 1 1 1 0
4.67909
121
1 0 0 1 1 0
5.53328
122
0 0 0 1 1 0
5.20303
123
0 1 1 0 0 0
5.00679
124
1 0 1 1 1 0
4.57847
125
0 1 1 1 0 0
4.79082
126
1 1 0 1 0 0
4.91901.
42. The method as claimed in claim 38 , wherein q IDcell [m] has one of values as expressed in:
ID cell
sequence
papr
0
88B7E232CDC83C
6.67057
1
5E260E301C4620
5.883
2
D691EC22D18E1C
4.95588
3
EA1A5F3245640C
4.92942
4
62ADBD0098A430
4.84232
5
B43C5102592228
5.97707
6
3C0BB31084EA14
5.2818
7
127AEE31B90504
4.62935
8
9ACD4C2374C53C
4.80191
9
4C5CE021B54B20
4.62839
10
C4EB0213688318
4.93818
11
F860B103EC6908
4.62239
12
70D7531121A934
6.23206
13
A646BF13E0272C
4.76556
14
2EF15D013DEF14
5.21957
15
4A30D2BAA965A0
6.73261
16
C20730A874AD98
4.9981
17
1416DCAAA52380
5.23977
18
9CA17EB878EBB8
5.59862
19
A02ACDA8FC01AC
6.75846
20
281D2FBA31C994
4.86729
21
FE8CC398E04788
5.57405
22
76BB21AA2D87B4
4.82303
23
584A7C8B1060A4
4.54948
24
D07DDEB9DDA09C
5.45765
25
06EC729B0C2684
4.91648
26
8EDB9089D1E6BC
3.95813
27
B2D023994504AC
6.03433
28
3AE7C18B88C494
4.50629
29
EC766D8949428C
4.80454
30
64C18FBB948AB4
4.94614
31
9A82B62CDF0708
4.54236
32
1235543E02C730
3.86311
33
C424F83CC34128
5.18297
34
4C935A0E1E8114
5.59137
35
7098A91E9A6300
5.51632
36
F8AF4B0C47AB38
4.64969
37
2EBEE72E862520
5.59862
38
A609051C4BED1C
6.56393
39
88F8183D660208
6.63257
40
004FBA2FABCA34
6.30837
41
D65E160D7A442C
5.76388
42
5E69B41FB78C14
5.17733
43
62E2070F336E00
6.50695
44
EA55A51DEEA63C
5.58222
45
3CC4493F2F2824
5.19814
46
B4F3AB0DF2E818
5.50865
47
D0B224966662A8
5.40503
48
58858684BBA290
4.48416
49
8E146A866A2C8C
5.59862
50
0623C894B7E4B0
4.76609
51
3A287BA43306A4
4.87033
52
B29FD9B6EEC69C
5.60052
53
648E35B42F4084
4.18939
54
ECB9D7A6F280BC
5.00411
55
C2C8CAA7DF67A8
4.91284
56
4A7F289502AF90
6.92296
57
9C6E8497C32988
5.39012
58
145966A50EE1B4
6.0232
59
28D2D5959A03A0
6.27241
60
A06537A747CB98
5.26582
61
76F49B85864584
5.47146
62
FE4339974B8DB8
6.43249
63
08A61410F5BE24
4.69906
64
8091F622287618
5.28969
65
56801A20E9F804
6.66865
66
DEB7B83224383C
5.90593
67
E23C4B22B0D228
6.13642
68
6A0BA9306D1210
4.9337
69
BC1A4532AC9C08
5.13715
70
34ADE720715430
5.05877
71
1ADCBA015CB320
5.42538
72
92EB5833817B18
5.21428
73
44FAB43150F504
4.27288
74
CC4D56038D353C
4.63478
75
F0C6A53309D72C
5.47216
76
78F10721C41710
6.49514
77
AEE0EB03059108
5.35897
78
26570911C85134
5.59862
79
4216C68A4CD380
5.36634
80
CA212498811BB8
4.79522
81
1C3088BA509DA0
5.03585
82
94876A888D5D9C
6.41538
83
A80CD9B809B78C
5.92329
84
20BB3BAAD47FB0
5.24541
85
F62A978805F1AC
6.41868
86
7E9D35BAC83994
5.47231
87
506C689BF5DE84
4.27052
88
D85B8A893816BC
4.98455
89
0E4A268BF990A4
4.85573
90
86FD84B9345098
4.66224
91
BA7677A9A0B28C
5.59862
92
3241D59B7D72B4
5.13782
93
E4D07999ACF4A8
5.73533
94
6C67DBAB713C94
6.31115
95
9224E23C3AB12C
4.76096
96
1A13400EF77914
4.43229
97
CC82AC0C36FF0C
4.52351
98
44B50E1EFB3730
4.16266
99
78BEFD2E6FDD20
5.72573
100
F0095F1CB21518
4.34746
101
2698B31E739300
6.81937
102
AE2F510CBE5B3C
5.86829
103
805E4C0D93BC28
5.22038
104
08E9AE1F4E7410
4.8724
105
DE78423D8FFA0C
6.7858
106
56CFA00F423A30
5.75267
107
6AC4531FC6D824
5.1796
108
E2F3F12D0B1018
6.00083
109
34E21D2FCA9604
4.6724
110
BCD5BF1D175638
4.8345
111
D81430A693DC88
4.05646
112
502392B45E1CB4
5.6271
113
86327EB69F9AAC
5.59862
114
0E85DC84425A90
4.90494
115
320E2FB4D6B080
5.95286
116
BA39CDA60B70BC
5.99303
117
6C286184CAFEA4
3.97648
118
E41FC396173698
5.71222
119
CA6E9E972AD98C
4.61398
120
42D97CA5F719B0
4.67909
121
94C89087369FA8
5.53328
122
1C7F3295FB5F90
5.20303
123
2074C1A56FB580
5.00679
124
A8C323B7B27DB8
4.57847
125
7E52CFB573F3A0
4.79082
126
F6E56D87BE3398
4.91901.
43. The method as claimed in claim 38 , wherein the interleaving scheme is defined by Π(r) as shown in:
Π(l)
11, 4, 12, 15, 0, 13, 5, 6, 14, 8, 10, 9, 1, 3, 2, 7, 16, 20,
31, 26, 22, 30, 27, 23, 19, 18, 17, 25, 21, 29, 24, 28,
wherein each number in the table indicates an index of a sub-carrier to which an element of the block code is one-to-one mapped.
44. The method as claimed in claim 37 , wherein R(r) is defined:
R
(
r
)
=
b
IDcell
+
1
g
∏
(
r
)
,
r
=
8
*
⌊
m
9
⌋
+
m
mod
9
=
0
,
1
,
…
,
31
,
wherein the number of the transmit antennas is three, the number of operation points of the FFT operation is 128, b k represents a k-th row vector of the block code generator matrix, k represents a value calculated by adding a cell identifier IDcell and 1, g u (0≦u≦47) represents a u-th column vector of the block code generator matrix, and u represents indicating an r-th element of a interleaving pattern according to an interleaving scheme Π(r).
45. The method as claimed in claim 44 , wherein the block code generator matrix is defined as:
G
=
[
g
0
g
1
…
g
31
]
=
[
01010101010101010000010101100011
00110011001100110001000100010001
00001111000011110101010101010101
00000000111111110011001100110011
00000011010101100000111100001111
00000101011000110000000011111111
00010001000100010000001101010110
]
.
46. The method as claimed in claim 44 , wherein T(k) has one of values as expressed in:
ID cell
sequence
papr
0
0 0 1 1
4.49505
1
0 1 1 0
4.11454
2
0 1 1 0
5.0206
3
1 1 0 0
5.06895
4
0 0 0 0
4.51602
5
1 0 1 0
4.96176
6
0 0 0 1
4.50134
7
0 1 0 0
5.29586
8
1 1 1 1
5.37387
9
1 0 0 0
4.6668
10
0 1 1 0
6.09482
11
0 0 0 1
6.11344
12
0 0 0 0
5.71868
13
0 0 0 0
4.12233
14
0 1 1 1
4.44864
15
1 0 1 0
4.42172
16
1 0 0 0
4.43697
17
0 1 1 0
5.96559
18
0 0 1 0
5.31882
19
1 1 1 0
5.1578
20
0 0 1 1
4.18834
21
1 1 0 0
5.74259
22
1 0 1 0
6.10238
23
1 1 1 0
4.50063
24
1 0 0 1
4.38448
25
1 1 0 1
4.33171
26
1 0 0 1
6.31759
27
1 1 1 0
6.33599
28
1 1 0 1
4.55537
29
0 1 0 0
4.83803
30
1 0 1 1
4.45342
31
1 0 1 0
5.12448
32
1 0 0 0
4.43697
33
0 0 0 1
4.90907
34
1 0 0 1
3.9985
35
1 0 1 0
6.0206
36
0 0 0 1
5.38301
37
1 0 0 0
3.66487
38
1 0 1 1
4.92205
39
0 1 1 1
5.53843
40
0 1 1 1
5.26838
41
1 1 0 1
5.16959
42
0 1 1 0
5.34282
43
0 0 0 0
5.15133
44
1 0 0 1
4.87551
45
1 1 1 1
4.79443
46
1 0 1 0
5.07783
47
0 0 1 0
4.99682
48
1 0 1 1
5.94242
49
1 0 0 1
4.77698
50
1 0 0 0
5.03657
51
0 0 1 1
4.46604
52
1 0 0 0
5.68568
53
1 1 0 1
5.01898
54
0 1 1 1
4.95591
55
1 0 0 1
5.27862
56
1 1 1 0
6.0317
57
1 0 1 1
4.64379
58
1 1 0 0
5.02863
59
0 0 0 0
6.04332
60
0 0 0 1
4.44083
61
0 1 1 1
5.23739
62
1 0 1 0
6.43278
63
0 1 1 1
4.43697
64
1 0 1 1
4.43697
65
1 1 1 0
4.50516
66
1 0 0 1
4.58929
67
0 1 1 0
4.85849
68
0 0 0 0
5.13149
69
0 0 1 0
4.59563
70
0 1 0 1
4.73083
71
1 0 0 0
4.43697
72
1 0 0 0
4.44072
73
1 0 1 0
5.47799
74
1 1 1 0
4.92135
75
1 0 0 0
5.5708
76
1 0 0 0
4.48634
77
0 0 0 1
5.3005
78
1 0 1 1
5.8947
79
1 1 0 0
5.38806
80
0 0 1 0
4.74777
81
0 1 0 0
4.82428
82
1 0 0 0
4.45469
83
1 0 1 1
5.66832
84
1 1 0 0
4.50856
85
1 0 0 1
4.97946
86
1 0 1 1
4.68484
87
0 1 0 1
4.50907
88
1 0 1 0
5.38228
89
0 0 1 0
5.22999
90
1 1 1 0
5.0672
91
0 1 0 0
5.59042
92
0 1 0 1
4.95926
93
0 0 1 1
3.80828
94
1 0 1 1
5.40268
95
0 0 1 0
5.97897
96
1 0 0 1
3.99109
97
1 0 0 1
5.06574
98
0 0 0 1
6.08269
99
1 0 0 0
4.39827
100
0 0 1 1
4.70382
101
0 1 0 1
4.60731
102
0 1 0 0
5.05357
103
1 0 1 0
3.30653
104
1 0 1 1
4.52546
105
1 1 0 0
5.53041
106
0 1 1 0
6.04148
107
1 0 1 0
4.88727
108
0 0 1 0
5.40024
109
1 1 0 0
4.566
110
0 1 1 1
4.92796
111
1 0 1 1
5.17459
112
0 1 0 1
4.65719
113
1 1 1 0
4.94826
114
1 1 1 0
5.62084
115
0 0 1 0
4.77778
116
0 1 0 0
4.43697
117
0 1 1 0
4.24182
118
0 0 0 0
6.37234
119
1 1 1 0
4.46408
120
0 1 1 0
5.23129
121
1 1 0 0
5.9557
122
0 0 1 0
5.1374
123
1 0 0 0
5.35576
124
0 1 0 0
4.82596
125
1 1 1 0
4.43697
126
1 1 1 0
4.74343.
47. The method as claimed in claim 44 , wherein q ID cell [m] has one of values as expressed in:
ID cell
sequence
papr
0
960E8D691
4.49505
1
9159C8F00
4.11454
2
075D46B90
6.0206
3
77C0C8D78
5.06896
4
E14E05948
4.51602
5
E69300278
4.96176
6
701D8D449
4.50134
7
B4784FD80
5.29586
8
22F6C2BB1
5.37387
9
25AB87080
4.6668
10
B3254A6B0
6.09432
11
C338870F9
6.11344
12
55360A4C8
5.71868
13
526B0FDF8
4.12233
14
C465C2BC9
4.44864
15
85C89B61A
4.42172
16
13C61602A
4.43697
17
141B53B1A
5.96559
18
82159EF2A
5.31882
19
F28853B62
5.1578
20
64069EF53
4.18834
21
63DBDB462
5.74259
22
F5D516252
6.10238
23
31B0D4B9A
4.50063
24
A7BE19DAB
4.38448
25
A0E35C49B
1.33171
26
36ED910AB
6.31759
27
46F05C6E2
6.33599
28
D0FED10D3
4.55537
29
D723D48E2
4.83803
30
41AD19FD3
4.46342
31
12D88DA2E
5.12448
32
84D600C1E
4.45697
33
830B0552F
4.90907
34
15858811F
5.9985
35
659805756
6.0206
36
F31688167
5.39301
37
F4CB8D856
3.66497
38
62C500E67
4.92205
39
A620C27AF
5.53849
40
302E4F39F
5.26838
41
37F34A8AF
5.16959
42
A17DC7E9E
5.34282
43
D1600A8D6
5.15133
44
47EE87CE7
4.87551
45
40V3C27D7
4.79443
46
D6VD0F3E6
5.07783
47
971016E34
4.99682
48
019E9BA05
5.94242
49
06C39E135
4.77698
50
90CD13504
5.03657
51
E0509E34D
4.46604
52
76DE1357C
5.68568
53
718356C4D
5.01898
54
E70DDBA7D
4.95591
55
23E8191B5
5.27862
56
B5E6D4784
6.0317
57
B2BB91EB5
4.64379
58
24B55C884
5.02863
59
542891CCC
6.04332
60
C2261C8FD
4.44083
61
C57B593CD
5.23739
62
53F5947FC
6.43278
63
9002C3E29
4.43697
64
068COEA19
4.43697
65
01D14B328
4.50516
66
97DF86519
4.58929
67
E7424B350
4.35848
68
714C86560
5.13148
69
761183E50
4.59563
70
E01F4E861
4.73083
71
24FA8C1A8
4.43697
72
B2F4O1598
4.44072
73
B5A9O4EA8
5.47799
74
29A7C9A98
1.92135
75
53BA04CD0
5.5708
76
CDB4898E0
4.4934
77
C2698C1D1
5.3005
78
54E7D17E1
5.8947
79
15CA58832
5.38806
80
834495E02
4.74777
81
8419D0532
4.82428
82
12971D102
4.45469
83
628A9074B
5.66892
84
F4845D17A
4.50856
85
F3D91884B
4.97946
86
65D795E7B
4.68484
87
A132575B3
4.50907
88
37BC9A382
2.38228
89
30619FAB2
5.22999
90
A6EP52E82
5.0672
91
D672DF8CA
5.59042
92
407C52CFB
4.95926
93
4721177CB
3.80828
94
D1AF9A3FB
5.40268
95
825A0E606
5.97897
96
14D483037
3.99109
97
138986907
5.06574
98
85070BD37
6.08269
99
F59A8697E
4.39827
100
63140BF4F
4.70382
101
64494E47F
4.60731
102
F247C304E
5.05357
103
36A201B86
3.30653
104
A0AC9CFB7
4.52546
105
A7F1C9486
5.53041
106
317F442B6
6.04148
107
41E2896FE
4.68727
108
D76C042CE
5.40024
109
D0B1419FE
4.566
110
463FCCFCF
4.92796
111
07929521D
5.17459
112
911C5842D
4.65719
113
96C15DF1C
4.94826
114
00CFD0B2C
5.62084
115
70521DF64
4.77778
116
E65CD0954
4.43697
117
E101D5264
4.24182
118
770F18454
6.37234
119
B3EADAF9C
4.46408
120
256457BAC
5.23129
121
22B95209C
5.9557
122
B4379F6AC
5.1374
123
C4AA120E4
5.35576
124
5224DF4D4
4.82596
125
55F9DAFE4
4.43697
126
C3F757BD4
4.74343.
48. The method as claimed in claim 37 , wherein R(r) is defined by:
R
(
r
)
=
B
IDcell
+
1
g
∏
(
r
)
,
r
=
8
*
⌊
m
9
⌋
+
m
mod
9
=
0
,
1
,
…
,
95
,
wherein the number of the transmit antennas is four, the number of operation points of the FFT operation is 512, b k represents a k-th row vector of the block code generator matrix, k represents a value calculated by adding a cell identifier IDcell and 1, g u (0≦u≦47) represents a u-th column vector of the block code generator matrix, and u represents indicating a r-th element of a interleaving pattern according to the interleaving scheme Π(r).
49. The method as claimed in claim 48 , wherein the block code generator matrix is defined as:
G
=
[
g
0
g
1
…
g
95
]
=
[
010101010101010100010001000100010000010101100011000000110101011000000000111111110000111100001111
001100110011001101010101010101010001000100010001000001010110001100000011010101100000000011111111
000011110000111100110011001100110101010101010101000100010001000100000101011000110000001101010110
000000001111111100001111000011110011001100110011010101010101010100010001000100010000010101100011
000000110101011000000000111111110000111100001111001100110011001101010101010101010001000100010001
000001010110001100000011010101100000000011111111000011110000111100110011001100110101010101010101
000100010001000100000101011000110000001101010110000000001111111100001111000011110011001100110011
.
]
.
50. The method as claimed in claim 48 , wherein the interleaving scheme is defined by Π(r) as shown in:
Π(l)
2, 6, 0, 10, 14, 11, 7, 3, 8, 15, 1, 12, 9, 4, 13, 5, 18, 26, 24,
17, 29, 19, 21, 16, 23, 22, 25, 28, 27, 31, 20, 30, 41, 34, 38,
44, 36, 43, 35, 32, 45, 47, 46, 39, 40, 33, 37, 42, 60, 56, 59,
61, 51, 62, 52, 49, 58, 48, 53, 50, 54, 57, 55, 63, 71, 77, 76,
74, 67, 66, 68, 75, 78, 64, 69, 79, 72, 70, 65, 73, 81, 92, 83,
87, 82, 94, 86, 88, 95, 91, 93, 90, 84, 85, 80, 89,
wherein each number in the table indicates an index of a sub-carrier to which an element of the block code is one-to-one mapped.
51. The method as claimed in claim 48 , wherein T(k) has one of values as expressed in:
ID cell
sequence
papr
0
CB3
6.26336
1
D47
5.27748
2
59D
4.9581
3
F21
5.05997
4
87E
6.51422
5
BFA
5.33856
6
4D4
7.0618
7
3E0
6.41769
8
3E4
4.87727
9
6F7
4.15136
10
8D0
5.86359
11
33E
5.68455
12
CA3
5.79482
13
119
5.29216
14
AA3
5.3423
15
EC5
5.40257
16
A08
5.63148
17
96C
5.44285
18
9D3
5.19112
19
5BC
5.41859
20
4BC
5.96539
21
D15
6.07706
22
A31
4.76142
23
4B3
4.67373
24
B0A
5.24324
25
BB7
4.81109
26
245
4.99566
27
B34
4.81878
28
A59
5.78273
29
807
5.59368
30
694
5.53837
31
6C6
6.42782
32
1F3
5.26429
33
573
4.94488
34
O7F
6.36319
35
9A3
5.91188
36
C86
5.36258
37
349
4.98064
38
C83
6.14253
39
EE0
5.95156
40
4C4
5.40169
41
634
4.82317
42
360
5.05168
43
7B6
5.20885
44
4A7
5.52378
45
0D4
6.47369
46
523
5.20757
47
F29
5.0776
48
A67
5.52381
49
251
5.10732
50
B8E
4.77121
51
580
5.38618
52
B6B
5.20069
53
DCC
6.18175
54
356
5.46713
55
7FB
6.23427
56
C6B
4.64117
57
956
5.81606
58
100
5.04293
59
DF0
6.56931
60
663
5.4996
61
602
5.72958
62
894
4.96955
63
247
5.37554
64
73E
5.29366
65
0FE
6.62956
66
5CB
4.88939
67
C59
4.30678
68
5B5
5.54517
69
E2D
5.27261
70
5F6
5.03828
71
9A9
5.25379
72
BDB
5.14859
73
AE7
5.39255
74
2C2
4.97124
75
6A3
6.20876
76
D3A
4.83271
77
741
5.5686
78
737
5.64126
79
7AC
5.17063
80
79F
5.0828
81
3F4
5.22885
82
99C
6.01707
83
755
6.51422
84
A44
4.93486
85
F67
4.86142
86
4D4
6.21941
87
810
4.25677
88
201
4.47647
89
054
6.8165
90
654
5.87238
91
F34
5.31419
92
4FF
6.88515
93
4AA
6.75475
94
E8D
6.10937
95
944
4.79898
96
478
4.77121
97
17E
5.66118
98
696
4.93494
99
31A
5.36534
100
9D7
4.78933
101
2A4
5.45932
102
35C
6.40963
103
CBD
5.39788
104
44C
4.38835
105
416
4.38145
106
6B6
5.5007
107
E79
5.6706
108
34F
5.62588
109
DC4
5.29578
110
586
5.00808
111
DF3
4.48385
112
F2B
5.53794
113
ED1
5.58523
114
686
5.71655
115
500
5.01001
116
BFB
5.89436
117
CB5
5.25553
118
99A
5.47731
119
43D
5.4871
120
161
6.18899
121
32D
5.35874
122
49D
5.46312
123
8BD
5.13605
124
2E9
5.70272
125
0F0
6.26171
126
144
5.50515.
52. The method as claimed in claim 48 , wherein q IDcell [m] has one of values as expressed in:
ID cell
sequence
papr
0
07B5C111880B98D21D714C95B59
6.26336
1
DFA04795906284114EC142D17E3
5.27748
2
D815C684186918C153B08E44CBB
4.9581
3
4AABF139B866B0A2069058858C3
5.05997
4
4D9E300820652C721BE1945039A
6.51422
5
958BB6AC380C34B349519A14F20
5.33856
6
923E779DA00FAC61552056C1478
7.0618
7
1C6D02BAF66B8CE64E89080512A
6.41769
8
1B5883AB7E68143652F844D0872
4.87727
9
C34D452F66090CF701484AD46C9
4.15136
10
C4F8841EEE0A94251D390601D90
5.86359
11
5646B3A35E0538464919D0C0BE8
5.68455
12
51F37292C60EA09654681C152B1
5.79482
13
8966B416DE67B85507D89211C0B
5.29216
14
8ED33527466C20871AA95E84753
5.3423
15
4E855A27A38F94B136C919CC181
5.40257
16
49B09B362B8408612AB8D5198D8
5.63148
17
91A51D9233E514A27808DB5D462
5.44285
18
96909C83BBEE8C7065791788F3B
5.19112
19
042EEB1E1BE920133159C149942
5.41859
20
031B6A0F83EAB8C32D288DDC01A
5.96539
21
DB8EEC8B9B83A0007F9803D8CA1
6.07706
22
DCBB2DBA038038D263E94F0D5F9
4.76142
23
5268589D45EC1857794011892AB
4.67373
24
55DD99ACDDE780856431DD1CBF2
5.24324
25
8DC81F28D58E984637815358749
4.81109
26
8A7D9E394D8504942AF01FCDC11
4.99566
27
18C3A984ED82A8F77FD0494C868
4.81878
28
1FF628B56581342563A18599131
5.78273
29
C7E3AE116DE028E430110BDDF8B
5.59368
30
C0566F20E5EBB0342D6047484D2
5.53837
31
1A24C23D294F4E58569D4A6C3CA
6.42782
32
1D11030CB14CD68A4BEC06B9A93
5.26429
33
C504C588B925CE4B195C08BD629
4.94488
34
C23104992126569B052DC468F71
6.36319
35
508F33049129FAFA500D12A9B09
5.91188
36
57BAF215092A62284C7C5E7C250
5.36258
37
8F2F34B111437EE91ECCD038CEB
4.98064
38
889AF5808948E23902BD1CAD7B3
6.14253
39
06C9C0A7CF2CC6BE181442290E0
5.95156
40
017C4196472F5E6C04658EBCBB8
5.40169
41
D969C7324F4642AF57D500F8502
4.82317
42
DE5C0623D745DE7F4AA44C2DC5A
5.05168
43
4C6271BE774A721E1F841AECA22
5.20885
44
4B57F08FEF49EACE02F5567937B
5.52378
45
9342360BE728F60D5145587DDC0
6.47369
46
9477F71A7F236ADF4C3414A8599
5.20757
47
54A1D83A9AC0DAEB6054D3A004B
5.0776
48
5394192B02C3463B7C251F75B13
5.52381
49
8B019FAF0AA25EF82F9511315A9
5.10732
50
8CB41EBE92A9C22832E4DDE4EF0
4.77121
51
1E0A690332AE6A4B67C40B25888
5.38618
52
19BFA832BAA5F69B7AB5C7B03D1
5.20069
53
C1AA6E96B2CCEE582805C9F4D6A
6.18175
54
C61FAFA73AC7768835740561632
5.46713
55
484CDAA07CAB560F2FDDDBA5361
6.23427
56
4FF95B91E4A0CEDF32AC9730A39
4.64117
57
97EC9D15FCC1D61C611C1974682
5.81606
58
90591C0474C24ACC7C6D55A1DDA
5.04293
59
02E76B99D4CDE6AF294D03209A2
6.56931
60
0552EAA84CC67E7F343C4FB52FB
5.4996
61
DD476C2C44A762BC668C41B1E40
5.72958
62
DAF2AD1DCCACFA6C7BFD0D64518
4.96955
63
072010B4AA4587D10AE25A4FBA1
5.37554
64
0015D1A532461B03179396DA2F8
5.29366
65
D80017012A2F07C2452398DEE42
6.62956
66
DF35D610B22C9F105852D40B71B
4.88939
67
4D8BE18D022337710D72828A163
4.30678
68
4A3E609C9A28ABA311034E5F83B
5.54517
69
92ABE6388241B36242B3C05B481
5.27261
70
951E67091A4A2FB25FC20CCEFD8
5.03828
71
1BCD120E5C2E0B37446BD20A88B
5.25379
72
1CF8933FD42D97E5591A9E9F3D3
5.14859
73
C4ED15BBCC4C8F260AAA10DBF69
5.39255
74
C35894AA444F17F416DB5C0E630
4.97124
75
5166E337E448BB9742FB0A8F249
6.20876
76
56D362067C4323475F8AC61AB10
4.83271
77
8E46E4A274223F840C3A481E5AB
5.5686
78
897365B3FC21A356114B04CBEF3
5.64126
79
49254AB319CA13623C2BC3C3820
5.17063
80
4E10CBA291C98BB0215A8F56379
5.0828
81
96050D2699A8977373EA8112FC2
5.22885
82
91B08C1711AB0BA16F9BCDC749A
6.01707
83
030EFBAAB1A4A7C03BBB1B460E3
6.51422
84
04BB3ABB29A73F1026CA57D39BA
4.93486
85
DCAEFC3F31C627D3747A59D7701
4.86142
86
DB1B7D0EA9CDBF01690B1542C58
6.21941
87
55C80809EFA19B8473A24B8690A
4.25677
88
527D893867A203546ED30713053
4.47647
89
8A680F9C6FC31F953D630957CE8
6.8165
90
8D5DCEADE7C08745211245C25B0
5.87238
91
1FE3F93057C72B26753213431C8
5.31419
92
18567801CFCCB7F66943DFD6A91
6.88515
93
C043FE85C7ADAB373AF3D19262A
6.75475
94
C7F67FB44FAE33E526829D47D73
6.10937
95
1D8492899302CD895C7F106386A
4.79898
96
1A3153980B01555B410EDCB6132
4.77121
97
C224951C13604D9A13BED2F2F88
5.66118
98
C511542D8B6BD1480FCF1E676D0
4.93494
99
572F23B03B6479295BEFC8A62A8
5.36534
100
509AA281B36FE5F9479E0473BF1
4.78933
101
880F2425AB0EF93A142E0A7754A
5.45932
102
8F3AA534330565E8095FC6E2C12
6.40963
103
01E9D0136569416F13F69866941
5.39788
104
065C5102ED62DDBD0E87D4F3018
4.38835
105
DE49D786E503C17C5D375AF7EA2
4.38145
106
D97C56B76D0859AE414616627FA
5.5007
107
4BC2612ACD07F5CF1566C0A3183
5.6706
108
4C77A03B55046D1D08178C76ADB
5.62588
109
94E2669F5D6D75DC5AA70272460
5.29578
110
9357E78ED56EE90C46D64EE7F38
5.00808
111
5381C88E308D5D3A6BB609AFBEB
4.48385
112
54B449BFB886C1EA76C7C53A2B3
5.53794
113
8CA1CF3BA0EFDD2925774B3EC09
5.58523
114
8B144E2A28EC41F9380607EB750
5.71655
115
192A799798E3E9986C26512A128
5.01001
116
1E9FB88600E8754A71579DBFA71
5.89436
117
C68A7E020889698B23E713FB4CB
5.25553
118
C1BFBF13908AF1593F96DF2EF92
5.47731
119
4F6CCA14C6E6D1DE253F81EA8C1
5.4871
120
48590B055EE54D0E384E4D3F199
6.18899
121
904C8DA1568451CF6AFEC37BD23
5.35874
122
97794C90CE8FC91D778F8FEE47B
5.46312
123
05C73B0D6E88617E23AFD96F003
5.13605
124
0272BA3CE68BFDAE3EDE95BA95B
5.70272
125
DA673C98EEEAE56F6D6E1BBE5E0
6.26171
126
DD52BD8976E17DBD701F576BCB8
5.50515.
53. A method for providing a pilot symbol for base station identification in a Multiple-Input Multiple-Output (MIMO) communication system having one or more transmit antennas, the method comprising:
generating, by a pilot signal generator, the pilot symbol,
wherein the pilot symbol is comprised of a first sequence having a good cell identification characteristic and a second sequence for reducing a peak-to-average power ratio (PAPR) for all of pilot symbols,
wherein when the number of the transmit antennas is two and an FFT operation point has a value of 128, the first sequence R(r) is determined by
R
(
r
)
=
b
IDcell
+
1
g
∏
(
r
)
,
r
=
8
*
⌊
m
9
⌋
+
m
mod
9
=
0
,
1
,
…
,
47
,
and
wherein b k represents a k-th row vector of a block code generator matrix, k represents a value calculated by adding a cell identifier IDcell and 1, g u represents a u-th column vector of the block code generator matrix, and u represents an r-th element of an interleaving pattern according to an interleaving scheme Π(r).
54. The method of claim 53 , wherein the first sequence is created by block-coding information to be transmitted from a base station to a mobile station.
55. The method of claim 54 , wherein the information to be transmitted from the base station to the mobile station is a cell identifier (ID).
56. The method of claim 53 , wherein the second sequence is created from a predetermined reference table taking the first sequence into account.
57. The method of claim 53 , wherein the pilot symbol for base station identification is determined by the following equation in which the first sequence and the second sequence are reflected,
q
ID
cell
[
m
]
=
{
R
(
8
*
⌊
m
9
⌋
+
m
mod
9
)
,
where
m
mod
9
=
0
,
1
,
…
,
7
m
=
0
,
1
,
…
,
N
used
N
t
-
1
T
(
⌊
m
9
⌋
)
,
where
m
mod
9
=
8
where N used denotes a number of used subcarriers, N t , indicates a number of the transmit antennas, R(r) denotes the first sequence, and T(−) denotes the second sequence.Cited by (0)
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